US2504172A - Dealkylation of alkyl pyridines - Google Patents
Dealkylation of alkyl pyridines Download PDFInfo
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- US2504172A US2504172A US654455A US65445546A US2504172A US 2504172 A US2504172 A US 2504172A US 654455 A US654455 A US 654455A US 65445546 A US65445546 A US 65445546A US 2504172 A US2504172 A US 2504172A
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07D—HETEROCYCLIC COMPOUNDS
- C07D213/00—Heterocyclic compounds containing six-membered rings, not condensed with other rings, with one nitrogen atom as the only ring hetero atom and three or more double bonds between ring members or between ring members and non-ring members
- C07D213/02—Heterocyclic compounds containing six-membered rings, not condensed with other rings, with one nitrogen atom as the only ring hetero atom and three or more double bonds between ring members or between ring members and non-ring members having three double bonds between ring members or between ring members and non-ring members
- C07D213/04—Heterocyclic compounds containing six-membered rings, not condensed with other rings, with one nitrogen atom as the only ring hetero atom and three or more double bonds between ring members or between ring members and non-ring members having three double bonds between ring members or between ring members and non-ring members having no bond between the ring nitrogen atom and a non-ring member or having only hydrogen or carbon atoms directly attached to the ring nitrogen atom
- C07D213/06—Heterocyclic compounds containing six-membered rings, not condensed with other rings, with one nitrogen atom as the only ring hetero atom and three or more double bonds between ring members or between ring members and non-ring members having three double bonds between ring members or between ring members and non-ring members having no bond between the ring nitrogen atom and a non-ring member or having only hydrogen or carbon atoms directly attached to the ring nitrogen atom containing only hydrogen and carbon atoms in addition to the ring nitrogen atom
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- This invention relates to the dealkylation of alkyl cyclic compounds. More particularly, the invention relates to the dealkylation of alkyl pyridines for the preparation of pyridine and alkyl pyridlnes of lower molecular weight.
- Pyridine has of itself many important uses. It is used medicinally for antiseptic-purposes and in the treatment of asthma and other diseases, such as some protozoa] diseases. It is often used as a denaturant for alcohol and as a catalyst in certain specific chemical reactions., such as the hydration of olens andI sulfonation of alcohols. Pyridine is one of the best organic solvents, readily dissolving a large number of technical -productssuch as fats, mineral oils, paints and rubber and thus is also useful as an extractive agent. It has the remarkable property of dissolving many metallic salts such as silver nitrate and mercurio acetate.
- Pure pyridine is mainly used for the production of plperidine (hexahydropyridine) which was one of the rst organic accelerators used in the vulcanization of rubber and is often used as a catalyst in synthetic organic chemistry. Pyridine and its derivatives are frequently used in the manufacture of dyestuils and in the dyeing of textiles.
- Pyridine is also the beginning material -for the production of numerous other valuable compounds. From pyridine various homologs may be formed which are also important in the ilelds in which pyridine is useful, particularly in the preparation of pharmaceutical products.' ⁇ Similarly, various derivatives of pyridine and of its homologs are produced and used extensively in the chemical industry.
- Pyridine and its homologs are formed in the destructive distillation of coal tar, bone oil and nitrogenous vegetable compounds and are present in the acid phase in the ammonium sulfate process. These compounds are also present in gases which are formed when coal is being coked and constitute the major portion of the nitrogenous compounds which may be present in petroleum oils in amounts up to 1 or 2 per cent. Recovery of the picolines, lutidines, collidines, and other homologs of pyridine from the nitrogenous constituents yields mixtures of these compounds in varying proportions. It is frequently desired to recover a larger proportion of pyridine itself or of certain specific homologs.
- Another object is to describe a dealkylation of alkyl pyridines.
- a still further object of the invention is to describe a process for the production of alkyl pyridines of relatively lower molecular weight from a mixture of heavier alkyl pyridines.
- Another object is to describe a. process for the dealkylation of alkyl pyridines in the presence of hydrocarbons forming stable alkylated compounds.
- process for the Still another object is to describe a process for I the dealkylation of alkyl pyridines in tite presence of aromatic hydrocarbons.
- An object is to describe a process for the dealkylation of alkyl pyridines in the presence of benzene and the formation of alkyl benzenes.
- the present invention comprises car- Y in which R may be methyl, ethyl or other alkyl radical; :c and :r' represent whole numbers between 0 and 5, y represents' a whole number; and z represents an integer between 0 and 6.
- R may be methyl, ethyl or other alkyl radical; :c and :r' represent whole numbers between 0 and 5, y represents' a whole number; and z represents an integer between 0 and 6.
- y i. e., the quantity of aromatics, depends somewhat on the nature of the substituted pyridine, such as the number of alkyl groups attached to the pyridine nucleus, and the proportion of aromatic compounds desired to be present according to the following discussion.
- the exact reaction is not thoroughly understood but a detailed knowledge of the reaction mechanics is not essential to the practice of the invention.
- the reaction may involve a direct exchange of a hydrogen of the aromatic reactant compound with an alkyl radical of the alkyl pyridine, or there may be present free alkyl radicals f 3 and hydrogen ions with constituent parts. Particularly with heavier alkyl radicals there may be a splitting of the radical with the formation of more radicals of fewer carbon atoms.
- Several of the possible reactions may occur simultaneously under the conditions of the process.
- ethyl pyridine may be dealkylated in the presence of benzene to form pyridine and ethyl benzene
- di-ethyl pyridine may be dealkylated to form pyridine and di-ethyi benzene or ethyl pyridine and ethyl benzene
- other alkyl pyridines v may be dealkylated to form various alkyl aromatic compounds and pyridine or simpler alkyl pyridines as more fully discussed below.
- the catalysts as described are preferably of the clay type. Fullers earth. pumice. diatoms.-
- Suitable silica-alumina catalyst may be prepared as described in either McKinney 2,142,324, issued January 3, 1939, or Hendrix et al. 2,342,196, issued February 22, 1944. Under the conditions of the process some cracking occurs and carbon is deposited on the catalyst, thereby reducing its catalytic activity. When the activity has become reduced or the catalyst inactivated, the activity may be restored by burning out the carbon with an oxygen-containing stream at elevated temperature. For greater eiliciency the catalyst should be used in the form of particles of such physical form that the catalyst may be.
- Carrier materials of suitable form and impregnated with active catalytic substances may also be used in the process. Small pellets, rods or cylinders are emcient and convenient forms for the catalytic material.
- the dealkylation may be controlled to prepare desired alkylated pyridine compounds which are less substihxted than the original compounds.
- coliidines may be dealkylated to various lutidines and picolines. lutidines to various picolines, and other pyridines of homogeneous or mixed alkyl substituents may be converted to alkyl pyridines having fewer alkyl
- the aromatic acceptor compounds e. g., benzene
- Undesirable heavy resinous compounds or light decomposition products which may form in small quantities may be removed (by means not shown) before returnof the recycle material to the conversion zone. ⁇
- the use of a large molar excess of the acceptor aromatic compound is advantageous both because oi' its diluent effect, which favors the dealkylation of the alkyl pyridines by lowering their partial pressure in the reaction zone, and because of its reaction to form valuable alkyl aromatics.
- the extent of dealkylation may be controlled to alarge degree by the ratio of aromatics to alkyl pyridine maintained in the dealkylation zone. The higher the concentration of the acceptor aromatic under suitable reaction conditions, the greater will be the extent of the dealkylation, and a ratio of aromatica to alkyl pyridine between about 1:1 and 10:1 or higher has been found to be satisfactory.
- the temperature of reaction is also a major factor in the extent of conversion.
- the temperature may be between 850 and 1200* F. Higher temperatures are generally required in the dealkylation of the alkylated pyridines having alkyl groups oi' fewer carbon atoms such as methyl and ethyl. Alkyl pyridines oi higher molecular weight alkyl groups are less resistant to dealkylation and react at lower temperature. For the same charging stock a relatively broad range of temperatures for conversion may be employed, the rate and extent of dealkylation depending to a large extent upon the temperature employed above that temperature at which conversion begins. With alkylated pyridines having ethyl and higher alkyl groups, reactions other than simple exchange of alkyl groups with hydrogen from the aromatica evidently occur.
- alkyl-substituted pyridines may be only partially dealkylated to form lower molecular weight pyridines of fewer alkyl constituents and the reacting aromatica may form mono, di, tri, etc., alkyl-substituted compounds as described above.
- Pressures may range from atmospheric to about 10 or 12 atmospheres with superatmospheric pressures usuallyl preferred.
- the pressure in the conversion zone and particularly. the partial pressure of the pyridine compound being s dealkylated affects materially the extent of the dealkylation which may occur.
- a mixture of isomers of ethyl pyridine together with an excess of benzene may be preheated to about 1100 F. and passed over fullers earth at a temperature of from 1000 to 1200 F. and under a pressure of about ten atmospheres.
- the eiliuent vapors are quickly cooled by quenching with benzene in a conventional heat exchange condenser and the components separated by fractional distillation. Unchanged benzene and ethyl pyridines are recycled to the process, and pyridine and ethyl benzene are recovered as the principal products of the reaction.
- the invention may also be applied to alkylated pyridines other than ethyl pyridines.
- the products may be pyridine, lutidine, toluene and/or xylene.
- complex mixtures of alkyl pyridines may be employed as sources for the preparation of pyridine, without regard to the particular alkyl benzenes formed.
- fractions rich in various and less highly substituted alkyl pyridines of specific compositions may be recovered from the process.
- a process for the dealkylation of alkyl pyridines which comprises treating alkylated pyridine compounds with a reactive aromatic compound'in the presence of a dealkylation catalyst and at a temperature between 850 and 1200 F.
- a process for the dealkylation of alkyl pyrii catalyst from the group consisting of clays and silica-alumina.
- a process for the dealkylation of alkyl pyridines and production of alkyl benzene which comprises heating a mixture of said alkyl pyridines and excess benzene and passing said heated mixture over an activated dealkylation catalyst between about 850 and 1200 F. to produce alkylated benzene compounds and pyridine compounds of lower molecular weight.
- a process for the dealkylation of alkyl pyridines which comprises heating a mixture of said alkyl pyridines with an excess of benzene, passing said heated mixture in contact with a dealkylating catalyst comprising fullers earth at a temperature between about 1000 and 1200 F. and under a pressure of about 10 atmospheres, quenching said treated mixture with benzene, and separating desired pyridine and alkylated benzene compounds.
- alkyl pyridines comprise an iscmeric mixture of ethyl pyridines, and in which pyridine and ethyl benzene are separated and unreacted ethyl pyridines and benzene are recycled.
- a process for producing relatively low molecular weight pyridine compounds from alkyl pyridine compounds of higher molecular weight which comprises heating a mixture of said higher molecular weight pyridine compounds and reactive aromatic compounds, passing said heated mixture through a chamber containing a dealkylation catalyst at a temperature between 850 and 1200 F., withdrawing the treated mixture, quenching said treated mixture with a quantity of said aromatic compound suiilcient to substantially cool the mixture. and recovering desired dealkylated pyridine compounds.
- a process for the production of pyridine from alkylated pyridine which comprises heating said alkylated pyridine and an excess of benzene at a temperature between about 1000 and 1200 F. and a pressure of about ten atmospheres in the presence of fullers earth, and separately recovering pyridine from a resulting product.
- alkylated pyridine is an isomeric mixture of ethyl pyridine.
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Description
April 18, 1950 p M ARNOLD 2,504,172
DEALKYLATION 0F ALKYL PYRIDINES Filed March 14, 1946 ATTORNEYS Patented Apr. 18, 1950 nEALxYLA'noN or Amr. mmlNEs Y Philip M. Arnold, Bartlesville, Okla., signor to Phillips Petroleum Company, a corporation o! Delaware Application March 14, 194s, seria1N.ns54,455
s claim.. (ci. zoo-29o) This invention relates to the dealkylation of alkyl cyclic compounds. More particularly, the invention relates to the dealkylation of alkyl pyridines for the preparation of pyridine and alkyl pyridlnes of lower molecular weight.
Pyridine has of itself many important uses. It is used medicinally for antiseptic-purposes and in the treatment of asthma and other diseases, such as some protozoa] diseases. It is often used as a denaturant for alcohol and as a catalyst in certain specific chemical reactions., such as the hydration of olens andI sulfonation of alcohols. Pyridine is one of the best organic solvents, readily dissolving a large number of technical -productssuch as fats, mineral oils, paints and rubber and thus is also useful as an extractive agent. It has the remarkable property of dissolving many metallic salts such as silver nitrate and mercurio acetate. Pure pyridine is mainly used for the production of plperidine (hexahydropyridine) which was one of the rst organic accelerators used in the vulcanization of rubber and is often used as a catalyst in synthetic organic chemistry. Pyridine and its derivatives are frequently used in the manufacture of dyestuils and in the dyeing of textiles.
Pyridine is also the beginning material -for the production of numerous other valuable compounds. From pyridine various homologs may be formed which are also important in the ilelds in which pyridine is useful, particularly in the preparation of pharmaceutical products.'` Similarly, various derivatives of pyridine and of its homologs are produced and used extensively in the chemical industry.
Pyridine and its homologs are formed in the destructive distillation of coal tar, bone oil and nitrogenous vegetable compounds and are present in the acid phase in the ammonium sulfate process. These compounds are also present in gases which are formed when coal is being coked and constitute the major portion of the nitrogenous compounds which may be present in petroleum oils in amounts up to 1 or 2 per cent. Recovery of the picolines, lutidines, collidines, and other homologs of pyridine from the nitrogenous constituents yields mixtures of these compounds in varying proportions. It is frequently desired to recover a larger proportion of pyridine itself or of certain specific homologs.
It is therefore an object of this invention to describe a process for the formation and recovery of pyridine.
It is a further object of thisinvention to describe a process for the formation of pyridine from its homologs. i
Another object is to describe a dealkylation of alkyl pyridines.
A still further object of the invention is to describe a process for the production of alkyl pyridines of relatively lower molecular weight from a mixture of heavier alkyl pyridines.
Another object is to describe a. process for the dealkylation of alkyl pyridines in the presence of hydrocarbons forming stable alkylated compounds.
process for the Still another object is to describe a process for I the dealkylation of alkyl pyridines in tite presence of aromatic hydrocarbons.
, An object is to describe a process for the dealkylation of alkyl pyridines in the presence of benzene and the formation of alkyl benzenes.
Other objects will be apparent from the following discussion andthe accompanying drawing in which The iigure is a diagrammatic 'sketch of one modiilcation of an arrangement for practicing the present invention.
In general the present invention comprises car- Y in which R may be methyl, ethyl or other alkyl radical; :c and :r' represent whole numbers between 0 and 5, y represents' a whole number; and z represents an integer between 0 and 6. The value of y, i. e., the quantity of aromatics, depends somewhat on the nature of the substituted pyridine, such as the number of alkyl groups attached to the pyridine nucleus, and the proportion of aromatic compounds desired to be present according to the following discussion.
The exact reaction is not thoroughly understood but a detailed knowledge of the reaction mechanics is not essential to the practice of the invention. The reaction may involve a direct exchange of a hydrogen of the aromatic reactant compound with an alkyl radical of the alkyl pyridine, or there may be present free alkyl radicals f 3 and hydrogen ions with constituent parts. Particularly with heavier alkyl radicals there may be a splitting of the radical with the formation of more radicals of fewer carbon atoms. Several of the possible reactions may occur simultaneously under the conditions of the process. Thus ethyl pyridine may be dealkylated in the presence of benzene to form pyridine and ethyl benzene, di-ethyl pyridine may be dealkylated to form pyridine and di-ethyi benzene or ethyl pyridine and ethyl benzene, and other alkyl pyridines vmay be dealkylated to form various alkyl aromatic compounds and pyridine or simpler alkyl pyridines as more fully discussed below. Y l The catalysts as described are preferably of the clay type. Fullers earth. pumice. diatoms.-
a rearrangement of the groups.
ceous earth and other clay-type catalysts, both natural and synthetic, as well as bauxite, silica- ,alumina and similar materials sui'i'er little loss in the process and are easily regenerated when spent. Suitable silica-alumina catalyst may be prepared as described in either McKinney 2,142,324, issued January 3, 1939, or Hendrix et al. 2,342,196, issued February 22, 1944. Under the conditions of the process some cracking occurs and carbon is deposited on the catalyst, thereby reducing its catalytic activity. When the activity has become reduced or the catalyst inactivated, the activity may be restored by burning out the carbon with an oxygen-containing stream at elevated temperature. For greater eiliciency the catalyst should be used in the form of particles of such physical form that the catalyst may be.
effectively disposed in the conversion zone and still permit the ready flow o! reactants therethrough and a suitable surface area of catalyst for contact with the reactants. Carrier materials of suitable form and impregnated with active catalytic substances may also be used in the process. Small pellets, rods or cylinders are emcient and convenient forms for the catalytic material.
The invention may be more clearly understood by reference to the accompanying drawing which illustrates one process for the practice of the invention. For convenience, the aromatic compound, acting as the alkyl acceptor, is described as benzene which is most generally used, although other aromatic compounds may be used as described. Alkyl'pyridines from line Ill and recycle alkyl pyridines from line II are admixed with benzene from line I2 and recycle benzene from line I3 and introduced into heater il. The heated mixture is passed by line I5 to dealkylation zone i8 and through line I1 to a, condenser I8. If desired, the eilluent from the dealkylation zone may be quickly cooled by quenching with water or hydrocarbon introduced through line 22. If quenching is employed. subsequent fractionation may be expedited if benzene is used for the quenching material. From condenser i8 the mixture passes through line I! to fractionator in which the unreacted alkyl pyridines and benzene are separated and recycled to the process through lines Il and Il, respectively. Pyridine and the alkyl benzene compounds are removed bv line 2l to further fractionation or to storage. For clarity of description various valves, pumps, and other standard equipment have been omitted from the drawing and description but will be familiar to those skilled in the art.
From more highly substituted pyridine compounds, the dealkylation may be controlled to prepare desired alkylated pyridine compounds which are less substihxted than the original compounds. Thus, coliidines may be dealkylated to various lutidines and picolines. lutidines to various picolines, and other pyridines of homogeneous or mixed alkyl substituents may be converted to alkyl pyridines having fewer alkyl Similarly, the aromatic acceptor compounds (e. g., benzene) may accept various numbers of homogeneous and mixed alkyl groups to form desirable alkylated compounds. Undesirable heavy resinous compounds or light decomposition products which may form in small quantities may be removed (by means not shown) before returnof the recycle material to the conversion zone.`
The use of a large molar excess of the acceptor aromatic compound is advantageous both because oi' its diluent effect, which favors the dealkylation of the alkyl pyridines by lowering their partial pressure in the reaction zone, and because of its reaction to form valuable alkyl aromatics. The extent of dealkylation may be controlled to alarge degree by the ratio of aromatics to alkyl pyridine maintained in the dealkylation zone. The higher the concentration of the acceptor aromatic under suitable reaction conditions, the greater will be the extent of the dealkylation, and a ratio of aromatica to alkyl pyridine between about 1:1 and 10:1 or higher has been found to be satisfactory. The temperature of reaction is also a major factor in the extent of conversion. As above-mentioned, the temperature may be between 850 and 1200* F. Higher temperatures are generally required in the dealkylation of the alkylated pyridines having alkyl groups oi' fewer carbon atoms such as methyl and ethyl. Alkyl pyridines oi higher molecular weight alkyl groups are less resistant to dealkylation and react at lower temperature. For the same charging stock a relatively broad range of temperatures for conversion may be employed, the rate and extent of dealkylation depending to a large extent upon the temperature employed above that temperature at which conversion begins. With alkylated pyridines having ethyl and higher alkyl groups, reactions other than simple exchange of alkyl groups with hydrogen from the aromatica evidently occur. Evidence indicates that a Splitting reaction may be involved with the formation of free unsaturated compounds such as ethylene in the dealkylation of ethyl pyridine. Some of the unsaturated compounds may then react with the available aromatic acceptors. With higher alkyl groups, such as amyl and higher radicals. cracking of the reacting group may also occur under the conditions of dealkylation to yield various products. Thus. for instance, in dealkylating amyl pyridines with benzene, other products, such as ethyl pyridine and propene from cracking of the amyl radical and propyl benzene from the subsequent alkylation of benzene with the propene, are formed as well as amyl benzene and pyridine. Di, tri, etc.. alkyl-substituted pyridines may be only partially dealkylated to form lower molecular weight pyridines of fewer alkyl constituents and the reacting aromatica may form mono, di, tri, etc., alkyl-substituted compounds as described above.
Pressures may range from atmospheric to about 10 or 12 atmospheres with superatmospheric pressures usuallyl preferred. The pressure in the conversion zone and particularly. the partial pressure of the pyridine compound being s dealkylated affects materially the extent of the dealkylation which may occur.
In a specific example of the invention, a mixture of isomers of ethyl pyridine together with an excess of benzene may be preheated to about 1100 F. and passed over fullers earth at a temperature of from 1000 to 1200 F. and under a pressure of about ten atmospheres. The eiliuent vapors are quickly cooled by quenching with benzene in a conventional heat exchange condenser and the components separated by fractional distillation. Unchanged benzene and ethyl pyridines are recycled to the process, and pyridine and ethyl benzene are recovered as the principal products of the reaction.
The invention may also be applied to alkylated pyridines other than ethyl pyridines. With the methyl pyridines, for example, the products may be pyridine, lutidine, toluene and/or xylene. Likewise, complex mixtures of alkyl pyridines may be employed as sources for the preparation of pyridine, without regard to the particular alkyl benzenes formed. Furthermore, with slight modifications of reaction conditions and with careful control of the fractionation, fractions rich in various and less highly substituted alkyl pyridines of specific compositions may be recovered from the process.
Although the invention has been described in connection with the addition of benzene to the reaction, other aromatic compoundswhich are reactive and will form alkyl-substituted products which are thermally stable under the conditions of the experiment may be used instead of benzene. Partially alkylated benzene and naphthalenes or alkylated naphthalenes have been tried and found moderately successful. However, better yields of dealkylated pyridines have been obtained using benzene. The greater thermal stability of alkylated benzenes probably accounts for the improved yield.
Various modifications of the invention will be apparent from the discussion and drawing and may be made in the process without departing from the spirit of the invention. The example is illustrative only and is not intended to limit the scope of the invention.
I claim:
l. A process for the dealkylation of alkyl pyridines which comprises treating alkylated pyridine compounds with a reactive aromatic compound'in the presence of a dealkylation catalyst and at a temperature between 850 and 1200 F.
2. A process for the dealkylation of alkyl pyrii catalyst from the group consisting of clays and silica-alumina.
4. A process for the dealkylation of alkyl pyridines and production of alkyl benzene which comprises heating a mixture of said alkyl pyridines and excess benzene and passing said heated mixture over an activated dealkylation catalyst between about 850 and 1200 F. to produce alkylated benzene compounds and pyridine compounds of lower molecular weight.
5. A process for the dealkylation of alkyl pyridines which comprises heating a mixture of said alkyl pyridines with an excess of benzene, passing said heated mixture in contact with a dealkylating catalyst comprising fullers earth at a temperature between about 1000 and 1200 F. and under a pressure of about 10 atmospheres, quenching said treated mixture with benzene, and separating desired pyridine and alkylated benzene compounds.
6. A process according to claim 5 in which the alkyl pyridines comprise an iscmeric mixture of ethyl pyridines, and in which pyridine and ethyl benzene are separated and unreacted ethyl pyridines and benzene are recycled.
7. A process for producing relatively low molecular weight pyridine compounds from alkyl pyridine compounds of higher molecular weight which comprises heating a mixture of said higher molecular weight pyridine compounds and reactive aromatic compounds, passing said heated mixture through a chamber containing a dealkylation catalyst at a temperature between 850 and 1200 F., withdrawing the treated mixture, quenching said treated mixture with a quantity of said aromatic compound suiilcient to substantially cool the mixture. and recovering desired dealkylated pyridine compounds.
8. A process for the production of pyridine from alkylated pyridine which comprises heating said alkylated pyridine and an excess of benzene at a temperature between about 1000 and 1200 F. and a pressure of about ten atmospheres in the presence of fullers earth, and separately recovering pyridine from a resulting product.
9. A process according to claim 8 in which said alkylated pyridine is an isomeric mixture of ethyl pyridine.
PHILIP M. ARNOLD.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,010,948 Egloi Aug. 13, 1935 2,141,611 Malishev Dec. 27, 1938 2,360,358 Mattox Oct. 17, 1944 OTHER REFERENCES Sidgwick, Organic Chemistry of Nitrogen (1942), Oxford Press, p. 522.
Claims (1)
1. A PROCESS FOR THE DEALKYLATION OF ALKYL PYRIDINES WHICH COMPRISES TREATING ALKYLATED PYRIDINE COMPOUNDS WITH A REACTIVE AROMATIC COMPOUND IN THE PRESENCE OF A DEALKYLATION CATALYST AND AT A TEMPERATURE BETWEEN 850* AND 1200*F.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2966399A (en) * | 1957-09-03 | 1960-12-27 | Phillips Petroleum Co | Safety systems for furnace |
US4118388A (en) * | 1976-08-11 | 1978-10-03 | Daicel, Ltd. | Process for producing pyridine |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2010948A (en) * | 1933-03-17 | 1935-08-13 | Universal Oil Prod Co | Manufacture of hydrocarbons |
US2141611A (en) * | 1933-12-02 | 1938-12-27 | Shell Dev | Method of alkylating cyclic compounds |
US2360358A (en) * | 1942-02-11 | 1944-10-17 | Universal Oil Prod Co | Manufacture of ethyl benzene |
-
1946
- 1946-03-14 US US654455A patent/US2504172A/en not_active Expired - Lifetime
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2010948A (en) * | 1933-03-17 | 1935-08-13 | Universal Oil Prod Co | Manufacture of hydrocarbons |
US2141611A (en) * | 1933-12-02 | 1938-12-27 | Shell Dev | Method of alkylating cyclic compounds |
US2360358A (en) * | 1942-02-11 | 1944-10-17 | Universal Oil Prod Co | Manufacture of ethyl benzene |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2966399A (en) * | 1957-09-03 | 1960-12-27 | Phillips Petroleum Co | Safety systems for furnace |
US4118388A (en) * | 1976-08-11 | 1978-10-03 | Daicel, Ltd. | Process for producing pyridine |
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